Thermally optimized phase change memory cells and methods of fabricating the same

ABSTRACT

A thermally optimized phase change memory cell includes a phase change material element disposed between first and second electrodes. The second electrode includes a thermally insulating region having a first thermal resistivity over the first electrode and a metallic contact region interposed between the phase change material element and the thermally insulating region, where the metallic contact layer has a second thermal resistivity lower than the first thermal resistivity.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application for patent is a continuation of U.S. patent application Ser. No. 15/607,095 by Boniardi et al., entitled “Thermally Optimized Phase Change Memory Cells and Methods of Fabricating the Same,” filed May 26, 2017, which is a continuation of U.S. patent application Ser. No. 14/861,259 by Boniardi et al., entitled “Thermally Optimized Phase Change Memory Cells and Methods of Fabricating the Same,” filed Sep. 22, 2015, which is a divisional of U.S. patent application Ser. No. 13/908,707 by Boniardi et al., entitled “Thermally Optimized Phase Change Memory Cells and Methods of Fabricating the Same,” filed Jun. 3, 2013, assigned to the assignee hereof, and each of which is expressly incorporated by reference herein.

FIELD

Subject matter disclosed herein relates to devices in integrated circuits generally, and in particular, to devices incorporating chalcogenide materials.

BACKGROUND

Devices incorporating phase change materials, e.g., chalcogenide materials, such as for example switches and storage elements, may be found in a wide range of electronic devices. For example, devices incorporating phase change materials may be used in computers, digital cameras, cellular telephones, personal digital assistants, etc. Factors that a system designer may consider in determining whether and how to incorporate phase change materials for a particular application may include, physical size, storage density, scalability, operating voltages and currents, read/write speed, read/write throughput, transmission rate, and/or power consumption, for example. Other example factors that may be of interest to a system designer include cost of manufacture, and/or ease of manufacture.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a three-dimensional illustration depicting a cross-point memory array according one embodiment.

FIG. 2A is an illustration depicting a cross-section of a phase change memory cell taken along a column line according to one embodiment.

FIG. 2B is an illustration depicting a cross-section of a phase change memory cell taken along a row line according to one embodiment.

FIG. 3A is an illustration depicting a cross-section of a phase change memory cell taken along a column line according to another embodiment.

FIG. 3B is an illustration depicting a cross-section of a phase change memory cell taken along a row line according to another embodiment.

FIG. 4A is an illustration depicting a cross-section of a phase change memory cell taken along a column line according to another embodiment.

FIG. 4B is an illustration depicting a cross-section of a phase change memory cell taken along a row line according to another embodiment.

DETAILED DESCRIPTION OF EMBODIMENTS

Devices incorporating phase change materials, e.g. memory devices, may be found in a wide range of electronic devices. For example, devices incorporating phase change materials may be used in computers, digital cameras, cellular telephones, personal digital assistants, etc. Factors related to devices incorporating phase change materials that a system designer may consider in determining the device's suitability for a particular application may include, physical size, storage density, scalability, operating voltages and currents, read/write speed, read/write throughput, transmission rate, and/or power consumption, for example. Other example factors that may be of interest to a system designer include cost of manufacture, and/or ease of manufacture.

In particular, memory devices incorporating phase change materials can provide several performance advantages over other memory devices, such as flash memory devices and dynamic random access memory devices (DRAM). For example, some phase change memory devices can be nonvolatile; i.e., physical and electrical states of the memory devices change do not change substantially over a retention time (e.g., longer than one year) without any external power supplied thereto. In addition, some phase change memory devices can provide fast read and write access time (e.g., faster than 10 nanoseconds) and/or high read and write access bandwidth (e.g., greater than 100 megabits per second). In addition, some phase change memory device can be arranged in a very high density memory array, e.g., a cross-point array having greater than 1 million cells in the smallest memory array unit connected with local metallization.

Performance of a phase change memory device with respect to above described characteristics depends on many factors. In particular, having good thermal isolation of the phase change material element within a memory device and low electrical resistances between the phase change material element and interfacing electrodes can reduce the energy required to program the device, as well as device-to-device thermal disturbance (i.e., thermal cross-talk). In addition, having low electrical resistance between the phase change material and the interfacing electrodes can also improve the signal-to-noise ratio of the memory device during a read operation. However, providing good thermal isolation can result in a tradeoff with low interfacial resistance, and vice versa. For example, interfacing electrodes often comprise metals, which can form low electrical resistance contacts with the phase change material element. However, such low contact materials tend to also be good thermal conductors, i.e., provide poor thermal isolation. Thus, there is a need for a thermally confined phase change memory device having a phase change material element having low electrical resistance and good thermal isolation. While embodiments are described herein with respect to memory arrays, it will be understood that a thermally confined phase change memory device with reduced interfacial resistance as described herein can also have application outside the memory array context.

FIG. 1 shows a portion of a cross-point memory array 10 having N×M phase change memory cells according to one embodiment of the present invention. The cross-point memory array 10 comprises first through Nth column lines 20-1, 20-2, . . . , and 2-N, first through Mth row lines 22-1, 22-2, . . . , and 22-M, and a plurality of memory cells disposed at at least a subset of the intersections formed by first through Nth column lines and first through Mth row lines.

The cross-point memory array 10 includes access lines in the form of first through Nth column lines 20-1, 20-2, . . . , and 20-N, which may be referred to digit lines, e.g., bit lines (BLs). The cross-point array 10 also includes crossing access lines in the form of first through Mth row lines 22-1, 22-2, . . . , and 22-M, which may be referred to as word lines (WLs). References to column lines and row lines, as well as their alternative designations, are interchangeable. The coordinate axis marker 12 in this embodiment indicates that first through Nth column lines 20-1, 20-2, . . . , and 20-N are extend along a y-direction (also referred to herein as a column direction) and first through Mth row lines 22-1, 22-2, . . . , and 22-M are oriented in a x-direction (also referred to herein as a row direction). As illustrated, first through Nth column lines 20-1, 20-2, . . . , and 20-N are substantially parallel to each other. Similarly, the first through Mth row lines 22-1, 22-2, . . . , and 22-M are substantially parallel to each other. However, other embodiments are possible, and word lines and digit lines can have non-perpendicular orientations. Typically row lines are parallel to one another and column lines are parallel to one another at an angle such that they cross with the row lines. As used herein, the term “substantially” intends that the modified characteristic needs not be absolute, but is close enough so as to achieve the advantages of the characteristic.

The cross-point memory array 10 further includes a plurality of memory cells disposed at at least a subset of the intersections formed by first through Nth column lines and first through Mth row lines. In this configuration, the cross-point memory array 10 includes up to N×M memory cells. In FIG. 1, however, for clarity, only four phase change memory cells are shown. As illustrated, the four phase change memory cells in the example of FIG. 1 include first through fourth memory cells 30 a-d at intersections of nth column line 20-n and mth row line 22-m, nth column line 20-n and (m+1)th row line 22-(m+1), (n+1)th column line 20-(n+1) and mth row line 22-m, and (n+1)th column line 20-(n+1) and (m+1)th row line 22-(m+1), respectively. In this example, it will be understood that each one of the four memory cells 30 a-d has two nearest neighboring cells in the x-direction, two nearest neighboring cells in the y-direction, and four next nearest neighboring cells in the diagonal direction between the x-direction and the y-direction. For example, in the x-direction, the first cell 30 a has two nearest neighboring cells, namely a fifth memory cell 30 e (not shown) at the intersection of (n−1)th column line 20-(n−1) and mth row line 22-m and the third memory cell 30 c at the intersection of (n+1)th column line 20-(n+1) and mth row line 22-m. In addition, the y-direction, the first cell 30 a has two nearest neighboring cells, namely an eighth memory cell 30 h (not shown) at the intersection of nth column line 20-n and (m−1)th row line 22-(m−1) and the second memory cell 30 b at the intersection of nth column line 20-n and (m+1)th row line 22-(m+1). In addition, in the two diagonal directions, the first cell 30 a has four next nearest neighboring cells, namely the fourth memory cell 30 d at the intersection of (n+1)th column line 20-(n+1) and (m+1)th row line 22-(m+1), a sixth memory cell 30 f (not shown) at the intersection of (n−1)th column line 20-(n−1) and (m+1)th row line 22-(m+1), a seventh memory cell 30 g (not shown) at the intersection of (n−1)th column line 20-(n−1) and (m−1)th row line 22-(m−1), and a ninth memory cell 30 i (not shown) at the intersection of (n+1)th column line 20-(n+1) and (m−1)th row line 22-(m−1).

In one embodiment, column lines may comprise a suitable conductive and/or semi conductive material including n-doped poly silicon, p-doped poly silicon, metals including Al, Cu, and W, conductive metal nitrides including TiN, TaN, and TaCN. In addition, top and bottom electrodes, described below, in various embodiments may comprise suitable conductive materials including doped semiconductors, such as n-doped poly silicon and p-doped poly silicon, and/or metallic materials, such as metals including C, Al, Cu, Ni, Cr, Co, Ru, Rh, Pd, Ag, Pt, Au, Ir, Ta, and W; conductive metal nitrides including TiN, TaN, WN, and TaCN; conductive metal silicides including tantalum silicides, tungsten silicides, nickel silicides, cobalt silicides, and titanium silicides; and conductive metal oxides including RuO2. In some embodiments, row lines may also comprise same or similar conductive and/or semiconductive materials as column lines.

Each of the memory cells 30 a-d in FIG. 1 according to one embodiment is configured in a stack configuration to include first through fourth selector nodes 38 a-d on one of mth and (m+1)th row lines 22-m and 22-(m+1), first through fourth bottom electrodes 36 a-d on selector nodes 38 a-d, first through fourth storage nodes 34 a-d on bottom electrodes 36 a-d, and first through fourth top electrodes 32 a-d on the storage nodes 34 a-d. Other embodiments of a stack configuration are possible. For example, the positions of storage nodes 34 a-d and selector nodes 38 a-d within a stack configuration may be interchanged with one another.

In one embodiment, each of the storage nodes 34 a-d includes a phase change material. Suitable phase change materials include chalcogenide compositions such as an alloy including at least two of the elements within the indium(In)-antimony(Sb)-tellurium(Te) (IST) alloy system, e.g., In₂Sb₂Te₅, In₁Sb₂Te₄, In₁Sb₄Te₇, etc., an alloy including at least two of the elements within the germanium(Ge)-antimony(Sb)-tellurium(Te) (GST) alloy system, e.g., Ge₈Sb₅Te₈, Ge₂Sb₂Te₅, Ge₁Sb₂Te₄, Ge₁Sb₄Te₇, Ge₄Sb₄Te₇, etc., among other chalcogenide alloy systems. The hyphenated chemical composition notation, as used herein, indicates the elements included in a particular mixture or compound, and is intended to represent all stoichiometries involving the indicated elements. Other chalcogenide alloy systems that can be used in phase change storage nodes include Ge—Te, In—Se, Sb—Te, Ga—Sb, In—Sb, As—Te, Al—Te, In—Ge—Te, Ge—Sb—Te, Te—Ge—As, In—Sb—Te, Te—Sn—Se, Ge—Se—Ga, Bi—Se—Sb, Ga—Se—Te, Sn—Sb—Te, In—Sb—Ge, Te—Ge—Sb—S, Te—Ge—Sn—O, Te—Ge—Sn—Au, Pd—Te—Ge—Sn, In—Se—Ti—Co, Ge—Sb—Te—Pd, Ge—Sb—Te—Co, Sb—Te—Bi—Se, Ag—In—Sb—Te, Ge—Sb—Se—Te, Ge—Sn—Sb—Te, Ge—Te—Sn—Ni, Ge—Te—Sn—Pd, and Ge—Te—Sn—Pt, for example.

When included in the memory cells 30 a-d, selector nodes 38 a-d may be electrically coupled to storage nodes 34 a-d through bottom electrodes 36 a-d on one side and electrically connected to row lines 22 on another side to form two terminal selector devices.

According to one embodiment, when selector nodes 38 a-d comprise a chalcogenide material, the two terminal selector device can be an Ovonic Threshold Switch (OTS). In this embodiment, a selector node may include a chalcogenide composition including any one of the chalcogenide alloy systems described above for a storage node. In addition, the selector node may further comprise an element to suppress crystallization, such as arsenic (As). When added, an element such as As suppresses crystallization by inhibiting any non-transitory nucleation and/or growth of the alloy. Accordingly, a selector node 38 a-d may be configured to switch to a conductive state when a potential exceeding a threshold voltage is applied across the selector node 38 a-d. In addition, the conductive state can be maintained while a sufficient holding current is maintained across the selector node. Examples include Te—As—Ge—Si, Ge—Te—Pb, Ge—Se—Te, Al—As—Te, Se—As—Ge—Si, Se—As—Ge—C, Se—Te—Ge—Si, Ge—Sb—Te—Se, Ge—Bi—Te—Se, Ge—As—Sb—Se, Ge—As—Bi—Te, and Ge—As—Bi—Se, among others.

According to another embodiment, selector nodes 38 a-d can form parts of semiconductor-based selector devices such as bipolar junction transistors (BJT). For example, in one embodiment, each one of selector nodes 38 a-d can be a p-type semiconductor to form a p-type emitter region of a PNP BJT. Each one of selector nodes 38 a-d can be connected to one of row lines 22, which can be an n-type semiconductor forming an n-type base region of the PNP BJTs. Each one of row lines 22 can in turn be disposed on a p-type semiconductor, e.g., p-type substrate, forming a p-type collector region of the PNP BJT. In the embodiment of FIG. 1, selector nodes 38 a and 38 c forming p-type emitter regions are connected by the row line 22-m forming a first common base region. The first common base region can be contacted to an upper metal level at a first base contact (not shown) farther along the x-direction. Similarly, selector nodes 38 b and 38 d forming p-type emitter regions are connected by the row line 22-(m+1) forming a second common base region. The second common base can be contacted to an upper metal level at a second base contact (not shown) farther along the x-direction. A person skilled in the art will understand that each of the row lines 22 can form a common base region connecting a suitable number of emitter regions. For example, the number of emitter regions in contact with a common base region can be 4, 8, 16, 32, 64, or more. A person skilled in the art will also understand that by analogy to a PNP BJT, an NPN BJT can also be formed in a similar fashion. Additionally, in other embodiments, p-type emitter regions are not connected to common base regions.

In one embodiment, any one of the memory cells disposed at an intersection formed by any one of first through Nth column lines 20-1, 20-2, . . . , and 20-N and first through Mth row lines 22-1, 22-2, . . . , 22-M may have a resistance state that may be a relatively high resistance state, also known as the RESET state, which can represent the state of a phase change material in a storage node 34 that includes a substantial amorphous region. Similarly, any one of the memory cells may have a resistance state that may be a relatively low resistance state, also known as the SET state, which can represent the state of a phase change material in a storage node 34 that is substantially crystalline. Under this implementation, high and low resistance states may correspond to the “1” state and a “0” state in a single bit-per-cell memory system. However, the states “1” and “0” as they relate to high and low resistance states may be used interchangeably to mean the opposite. For example, a high resistance state may be referred to as a“0” state, and a low resistance state may be referred to as a “1” state.

In other embodiments, any one of the memory cells disposed at an intersection formed by any one of the column lines and row lines may have a resistance state that may be an intermediate resistance state. For example, any one of the memory cells may have a resistance state that is any one of first, second, third, and fourth resistance states, wherein the first resistance state is more resistive than the second resistance state, the second resistive state is more resistive than the third resistive state, and the third restive state is more resistive than the fourth state. Under this implementation, first, second, third, and fourth resistance states may correspond to the “11,” “10,” “01”, and “00” states in a two bits-per-cell memory system. Yet other embodiments are possible, where first through eighth resistance states represent the states in a three-bits-per cell memory system, and where first through sixteenth resistance states represent the states in a four-bits-per cell memory system.

In one embodiment, each one of the memory cells disposed at an intersection formed by any one of first through Nth column lines 20-1, 20-2, . . . , and 20-N and any one of first through Mth row lines 22-1, 22-2, . . . , and 22-M may be accessed by an access operation. An access operation may be a write access operation, an erase access operation, or a read access operation. A write access operation, otherwise known as the program operation or a RESET operation, changes the resistance state of the memory cell from a relatively low resistance state to a relatively high resistance state. Similarly, an erase operation, otherwise known as the SET operation, changes the resistance state of the memory cell from a relatively high resistance state to a relatively low resistance state. However, the terms “write” and “erase” as they relate to RESET and SET operations may be used interchangeably to mean the opposite. For example, an erase operation may be referred to as a SET operation, and a program or write operation may be referred to as a RESET operation.

In an embodiment, each one of the memory cells disposed at an intersection formed by any of the column lines and row lines may be accessed individually in a bit-addressable access mode. In a bit-addressable access mode, a memory to be accessed may be a memory cell 30 a located at an intersection formed by a selected nth column line 20-n and a selected mth row line 22-m. An access voltage V_(ACCESS), which may be a SET access voltage V_(SET), a RESET access voltage V_(RESET), or a read access voltage V_(READ), may be applied across the memory cell 30 a of this example by applying the access voltage across the selected nth column line 20-n and the selected mth row line 22-m.

In one embodiment, a memory cell such as the memory cell 30 a at the intersection of the selected column line 20-n and the selected row line 22-m accessed while preventing the remaining cells from getting accessed. This can be achieved by applying a voltage V_(ACCESS) across the memory cell 30 a while allowing for voltages substantially lower than V_(ACCESS) to be applied across the rest of the cells, for example memory cells 30 b-d. In one embodiment, this is obtained by applying V_(ACCESS) to one end of the selected column line (nth column line 20-n in this example) while keeping one end of the selected row line (mth row line 22-m in this example) at a low voltage V_(LOW), which may be at ground potential. Concurrently, a voltage V_(COL INHIBIT) is applied across all remaining column lines (first through 20-(n−1) and 20-(n+1) through 20-N column lines in this example). In addition, a voltage V_(ROW INHIBIT) is applied across all remaining row lines (first through 20-(m−1) and 20-(m+1) through 20-M row lines in this example). Under this configuration, a voltage of about V_(ACCESS) is dropped between the nth column line 20-n and the mth row line 22-m across the memory cell 30 a (which may be referred to hereinafter as a “target cell”). In addition, a voltage of about (V_(ACCESS)−V_(ROW INHIBIT)) is dropped across inhibited cells such as the memory cell 30 b along the selected nth column line 20-n (which may be referred to hereinafter as “A-type cells”), and a voltage of about V_(COL INHIBIT) is dropped across inhibited cell such as the memory cell 30 c along the selected mth row line 20-m (which may be referred to hereinafter as “B-type cells”). In addition, a voltage approximately equal to (V_(COL INHIBIT)−V_(ROW INHIBIT)) is dropped across all remaining deselected cells such as the memory cell 30 d (which may be referred to hereinafter as “C-type cells”).

In one particular embodiment, V_(ROW INHIBIT) and V_(COL INHIBIT) is selected to be a voltage substantially equal to V_(ACCESS)/2. In this implementation, a voltage substantially equal to V_(ACCESS)/2 is dropped across A-type cells (e.g. the memory cell 32 b) and across B-type cells (e.g. the memory cell 30 c) while a voltage substantially equal to zero is dropped across C-type cells (e.g. the memory cell 30 d). This embodiment may be utilized, for example, when the selector included in the memory cell is an Ovonic Threshold Switch (OTS).

In another particular embodiment, V_(ROW INHIBIT) is selected to be at V_(ACCESS) and V_(COL INHIBIT) is selected to be at V_(LOW) (which may be at ground potential). In this implementation, a voltage substantially equal to zero is dropped across type A cells (e.g. the memory cell 32 b) and across type B cells (e.g. the memory cell 30 c) while a voltage substantially equal to −V_(ACCESS) is dropped across C-type cells (e.g. the memory cell 30 d). This embodiment may be utilized, for example, when the selector included in the memory cell is a bipolar junction transistor (BJT).

Other embodiments are possible. For example, a voltage of V_(ACCESS) across the target cell can be obtained by applying a suitable positive fraction of V_(ACCESS) such as +½ V_(ACCESS) to one end of the selected column while applying a suitable negative fraction of V_(ACCESS) such as −½ V_(ACCESS) is applied to one end of the selected row. Similarly, suitable fractions of V_(ACCESS) can be chosen as V_(ROW INHIBIT) and V_(COL INHIBIT). A person skilled in the art will recognize that choosing a bias scheme depends on many factors, such as the selector device type, an overall cell current-voltage (IV) characteristics, number of columns, number of rows, and the overall array size, among others. A person skilled in the art will also recognize that the actual voltages that similarly situated cells receive may deviate from the voltage applied at one of the ends of a column or a row due to various parasitic resistances and capacitances to which a particular cell may be subject to under a particular access condition.

FIGS. 2A and 2B illustrate cross-sectional views of the cross point memory array 10 of FIG. 1 viewed in a direction parallel to the x-direction and the y-direction, respectively. The cross sectional views are annotated with circuit representations demonstrating relevant resistive elements during an access operation of a target cell 30 a as described above.

In FIG. 2A, for clarity, only two phase change memory cells are shown along a column line 20 in the y-direction. As illustrated, the two phase change memory cells include the first and second memory cells 30 a and 30 b along a column line 20. As discussed in FIG. 1, each of the first and second memory cells 30 a and 30 b is configured in a stack configuration to include first and second selector nodes 38 a and 38 b on a row lines 22, first and second bottom electrodes 36 a and 36 b on selector nodes 38 a and 38 b, first and second storage nodes 34 a and 34 b on bottom electrodes 36 a and 36 b, and first and second top electrodes 32 a and 32 b on storage nodes 34 a and 34 b.

Similarly, in FIG. 2B, for clarity, only two phase change memory cells are shown along a row line 22 in the x-direction. As illustrated, the two phase change memory cells include the first and third memory cells 30 a and 30 c along a row line 22. As discussed in FIG. 1, each of the memory cells 30 a and 30 c is configured in a stack configuration to include first and third selector nodes 38 a and 38 c on a row line 22, first and third bottom electrodes 36 a and 36 c on selector nodes 38 a and 38 c, first and third storage nodes 34 a and 34 c on bottom electrodes 36 a and 36 c, and first and third top electrodes 32 a and 32 c on storage nodes storage nodes 34 a and 34 c.

In addition, according to the illustrated embodiment in FIGS. 2A and 2B, adjacent memory cells in the y-direction can be interposed by inter-column dielectric regions 48 and adjacent memory cells in the x-direction can be interposed by inter-row dielectric regions 50. The inter-column dielectric regions 48 and inter-row dielectric regions 40 can be filled with suitable insulating material such as SiO₂ and Si₃N₄. Under these configurations, storage nodes are surrounded in x and y directions by dielectrics and the array process architecture may be referred to as fully-confined array architecture. When selector nodes 38 a-d include emitter regions of BJTs, the inter-column dielectric regions 48 and inter-row dielectric regions 50 adjacent to the selector nodes 38 a-d can include shallow trench isolation dielectrics.

In the fully-confined array architecture of the cross-point memory array 10 in FIGS. 2A and 2B, when accessed in a bit-addressable access mode, the memory cell 30 a to be accessed (i.e., the target memory cell) may be memory cell 30 a located at an intersection formed by an nth column 20-n and an mth row 22-m. An access voltage V_(ACCESS), which may be a SET access voltage V_(SET), a RESET access voltage V_(RESET), or a read access voltage V_(READ), may be applied across the target cell of this example by applying the access voltage V_(ACCESS) across the a first terminal 12 a and a second terminal 12 b of an access circuit path 12. First and second terminals 12 a and 12 b can represent ends of the nth column 20-n and the mth row 22-m. V_(ACCESS) and the associated current I_(ACCESS) will result in energy dissipation at various points along the access circuit path 12.

The access circuit path 12 includes first through third resistors 42, 44, and 46 connected in electrical series between first and second terminals 12 a and 12 b. When the storage node 34 a is in the SET state, the first through third resistors 42, 44, and 46 can have first through third low resistance state (LRS) resistances R_(LRS1), R_(LRS2), and R_(LRS3). When the storage node 34 a is in the RESET state, the first through third resistors 42, 44, and 46 can have first through third high resistance state (HRS) resistances R_(HRS1), R_(HRS2), and R_(HRS3). Contributions to LRS resistances R_(LRS1), R_(LRS2), and R_(LRS3) and HRS resistances R_(HRS1), R_(LRS2), and R_(LRS3) can originate from various regions across the first memory cell 30 a. For example, regions that contribute to R_(LRS1) and R_(HRS1) can include a bulk material of the top electrode 32 a and a first interface between the top electrode 32 a and the storage node 34 a. Additionally, regions that contribute to R_(LRS2) and R_(HRS2) can include a bulk material of the storage node 34 a. Additionally, regions that contribute to R_(LRS3) and R_(HRS3) can include a second interface between the storage node 34 a and the bottom electrode 36 a and a bulk material of the bottom electrode 36 a. It is to be understood that while other regions may also contribute substantially to the overall resistance between the first and second terminals 12 a and 12 b, only first through third resistors 42, 44, and 46 are represented in the access circuit path 12 for clarity. In addition, other circuit paths can exist, for example, through the second memory cell 30 b, which are not shown nor discussed for clarity.

As a person skilled in the art will understand, in some implementations, an I_(ON)/I_(OFF) ratio can be an important consideration in designing a memory cell. An ON/OFF ratio can be proportional to the ratio (R_(HRS1)+R_(HRS2)+R_(HRS3))/(R_(LRS1)+R_(LRS2)+R_(LRS3)). When R_(HRS2)>>R_(HRS1)+R_(HRS3) and R_(LRS2)>>R_(LRS1)+R_(LRS3), the ON/OFF ratio can be dominated by the ratio R_(HRS2)/R_(LRS2). Under this circumstance, the ON/OFF ratio can be desirably dominated by the resistance ratio of the bulk resistances of the storage node 34 a in RESET and SET states. On the other hand, when R_(HRS2)<<R_(HRS1)+R_(HRS3) and R_(LRS2)<<R_(LRS1)+R_(LRS3), the ON/OFF ratio can be relatively independent of the ratio R_(HRS)2/R_(LRS)2. Under this circumstance, the ON/OFF ratio can be undesirably dominated by the resistance values of the first and second interfaces between the storage node 34 and the top and bottom electrodes 32 a and 36 a and/or the resistance values of the bulk materials of the top and bottom electrodes 32 a and 36 a. Thus, from an ON/OFF ratio point of view, relatively low LRS and HRS resistances R_(LRS1), R_(LRS3), R_(HRS1), and R_(HRS3) of the first and third resistors 42 and 46 and relatively high LRS and HRS resistances R_(LRS2) and R_(HRS2) of the second resistor 44 can be preferred.

The energy efficiency of SET and RESET operations can also be proportional to heats generated at various regions of the memory cell. In some implementations, it may be desirable to have self-heating of the storage node dominate over heats generated in other regions. From this standpoint, it may be desirable to have R_(HRS2)>>R_(HRS1)+R_(HRS3) and R_(LRS2)>>R_(LRS1)+R_(LRS3). When a voltage V_(ACCESS) is applied between the first and second terminals 12 a and 12 b of the access circuit path 12, voltages proportional to respective LRS and FIRS resistances can drop across first, second, and third resistors 42, 44, and 46. For example, when V_(ACCESS)=V_(RESET) is applied between the first and second terminals 12 a and 12 b, first, second, and third voltages V_(RESET1), V_(RESET2), and V_(RESET3) can drop across first, second, and third resistors 42, 44, and 46, respectively. The resulting current I_(RESET)=V_(RESET)/(R_(LRS1)+R_(LRS2)+R_(LRS3)) can result in generation of first, second, and third RESET heats Q_(RST1)=I_(RESET) ²R_(LRS1) and Q_(RST2)=I_(RESET) ²R_(LRS2), and Q_(RST3)=I_(RESET) ²R_(LRS3), respectively. Thus, for maximum energy efficiency of the RESET operation, it may be desirable to have R_(LRS2)>>R_(LRS1)+R_(LRS3) such that more of the access energy is spent on self-heating of the storage node 34 a compared to heating the interfaces.

Similarly, when V_(ACCESS)=V_(SET) is applied between the first and second terminals 12 a and 12 b, first, second, and third voltages V_(SET1), V_(SET2), and V_(SET3) can drop across first, second, and third resistors 42, 44, and 46, respectively. In addition, the resulting current I_(SET)=V_(SET)/(R_(HRS1)+R_(HRS2)+R_(HRS3)) can result in generation of first, second, and third SET heats Q_(SET1)=I_(SET) ²/(R_(HRS1) and Q_(SET2)=I_(SET) ²R_(HRS2), and Q_(SET3)=I_(SET) ²R_(HRS3), respectively. Thus, for maximum energy efficiency of the SET operation, it may also be desirable to have R_(HRS2)>>R_(HRS1)+R_(HRS3) such that more of the access energy is spent on self-heating of the storage node 34 a compared to the interfaces.

The energy efficiencies of SET and RESET operations can also be proportional to confinement of heat in the storage node during SET and RESET operations. Accordingly, the performance of a memory cell can be improved minimizing heat loss from the storage node. As illustrated in FIGS. 2A and 2B, there can be heat loss in six directions. A first heat Q₁ can be lost from the storage node 34 a in the z-direction towards the top electrode 32 a. A second heat Q₂ can be lost from the storage node 34 a in the z-direction towards the bottom electrode 36 a. A third heat Q₃ can be lost from the storage node 34 a in opposite y directions towards adjacent storage nodes 34 b and 34 h (not shown). A fourth heat Q₄ can be lost from the storage node 34 a in opposite x-directions towards adjacent storage nodes 34 c and 34 e (not shown).

First through fourth lost heats Q₁-Q₄ can depend on many factors. Generally, one-dimensional heat flux can be expressed as being proportional to κ(dT/dx), where dT/dx is the temperature gradient one dimension in the direction of the heat flow and κ is the thermal conductivity of the heat transfer medium, which is inversely proportional to the thermal resistivity of the heat transfer medium. In this connection, first through fourth heats Q₁-Q₄ can be characterized as being inversely proportional to first through fourth thermal resistances R_(TH1)-R_(TH4) associated with first through fourth heats Q₁-Q₄. In the fully-confined array architecture of the cross-point memory array 10, contributions to first through fourth thermal resistances R_(TH1)-R_(TH4) can originate from various regions connected to the first memory cell 30 a. For example, regions that contribute to R_(TH1) can include a bulk material of the top electrode 32 a and a first interface between the top electrode 32 a and the storage node 34 a. Additionally, regions that contribute to R_(TH2) can include the second interface between the storage node 34 a and the bottom electrode 36 a and a bulk material of the bottom electrode 36 a. Additionally, regions that contribute to R_(TH3) can include a third interface between the storage node 34 a and adjacent inter-column dielectric region 48 as well as a bulk material of the inter-column dielectric region 48. Additionally, regions that contribute to R_(TH4) can include a fourth interface between the storage node 34 a and adjacent inter-column dielectric region 50 as well as a bulk material of the inter-column dielectric region 50. It is to be understood that while other regions may also contribute substantially to the overall thermal resistance surrounding storage node 34 a, only first through fourth thermal resistances R_(TH1)-R_(TH4) are discussed for clarity.

Excessive loss of heat in the x and y directions can also lead to thermal disturb of adjacent cells during programming a target cell (sometimes referred to as program disturb). A program disturb occurs when the heat generated by performing a SET operation or a RESET operation on the target memory cell results in a heat transfer to an adjacent memory cell (sometimes referred to as a victim cell) such that an adjacent cell in a RESET state at least partially transforms to a SET state. As a general rule, the time for phase transformation t_(cryst) of a storage node at a given temperature T can be governed by an Arrhenius relationship (1).

$t_{cryst} \propto {\exp\limits^{{- 14} -}\left( \frac{E_{A}}{k_{\beta}T} \right)}$

where E_(a) is the activation energy, kB is the Boltzmann constant, and T is the temperature of the victim cell. Due to the exponential nature of the crystallization kinetics, a small increase in the temperature of the victim cell can lead to a substantial degradation of program disturb time-to-fail. In addition, a time required to disturb a victim cell can be cumulative; i.e., while a single RESET operation having a RESET pulse duration of t_(RESET) may not be sufficient to cause a significant program disturb, repetition of many RESET operations can result in a program disturb. In this connection, minimizing loss of third and fourth heats Q₃ and Q₄ in FIGS. 2A and 2B, which can be achieved by maximizing R_(TH3) and R_(TH4) discussed above, can lead to an improvement in program disturb performance of the cross-point memory array 10.

In the embodiment of FIG. 2A, the column line 20, top electrodes 32 a and 32 b, storage nodes 34 a and 34 b, bottom electrodes 36 a and 36 b, selector nodes 38 a and 38 b, and row lines 22 have first through sixth lateral dimensions in the y-direction d_(1a), d_(2a), d_(3a), d_(4a), d_(5a), and d_(6a), respectively. In addition, a seventh lateral dimension in the y-direction d_(7a) represents a spacing between adjacent memory cells 30 a and 30 b. The first lateral dimension in the y-direction d_(1a) represents a column length of column lines 20 of the cross-point memory array 10. In one embodiment, a substantially similar second through sixth lateral dimensions in the y-direction d_(2a), d_(3a), d_(4a), d_(5a), and d_(6a), can result from patterning and etching within a single photo mask level a stack between and including the top electrodes 32 a and 32 b and row lines 22.

Similarly, in the embodiment of FIG. 2B, the column lines 20, top electrodes 32 a and 32 c, storage nodes 34 a and 34 c, bottom electrodes 36 a and 36 c, selector nodes node 38 a and 38 c, and row line 22 have first through sixth lateral dimensions in the x-direction d_(1b), d_(2b), d_(3b), d_(4b), d_(5b), and d_(6b), respectively. In addition, a seventh lateral dimension in the x-direction represents the spacing between adjacent memory cells 30 a and 30 c in the x-direction. The sixth lateral dimension in the x-direction d_(7b) represents a row length of row lines 22 in the cross-point memory array 10. In one embodiment, a substantially similar first through fifth lateral dimensions in the x-direction d_(1b), d_(2b), d_(3b), d_(4b), and d_(5b) result from patterning and etching within a single photo mask level a stack between and including the columns 20 and storage nodes 32 a and 32 b.

The first lateral dimension in the y-direction d_(1a) representing a column length is a function of the number of row lines M the column line 20 traverses in the y-direction. For example, in an array with M row lines where d_(7a) represents the spacing between adjacent memory cells in the y-direction, d_(1a) may be at least (M×d_(6a))+(M×d_(7a)). Similarly, the sixth lateral dimension in the x-direction d_(6b) representing a row length is a function of the number of column lines N the row line 22 traverses in the x-direction. For example, in an array with N column lines where d_(7b) represents the spacing between adjacent memory cells in the x-direction, d_(6b) may be at least (N×d_(1b))+(N×d_(7b)).

In the fully-confined array architecture of the cross-point memory array 10 according to one embodiment, d_(2a)-d_(6a) in FIG. 2A can be selected to be the range between about 40 nm and 60 nm, for example 50 nm. In another embodiment, d_(2a)-d_(6a) can have dimensions selected to be the range between about 25 nm and 40 nm, for example 35 nm. In another embodiment, d_(2a)-d_(6a) can have dimensions selected to be the range between about 18 nm and 25 nm, for example 20 nm. In yet another embodiment, d_(2a)-d_(6a) can have dimensions selected to be the range between about 5 nm and 18 nm, for example 14 nm. Smaller dimensions are yet possible, limited only by the lithographic capability employed by the person skilled in the art. Similar ranges of dimensions can be chosen for d_(1b)-d_(5b) in FIG. 2B.

According to the embodiments of FIGS. 2A and 2B, column lines 20 have a first thickness h₁, the top electrodes 32 a-c have a second thickness h₂, the storage node 34 a-c have a third thickness h₃, the bottom electrode 36 a-c have a fourth thickness h₄, the selector nodes 38 a-c have a fifth thickness h₅, and row lines 22 have a sixth thickness h₆. In one embodiment, the first thickness h₁ has a thickness selected to be the range between about 10 nm and 100 nm, for example 35 nm, the second thickness h₂ has a thickness selected to be the range between about 10 nm and 50 nm, for example 25 nm, the third thickness h₃ has a thickness selected to be the range between about 5 nm and 50 nm, for example 25 nm, and the fourth thickness h₄ has a thickness selected to be the range between about 10 nm and 100 nm, for example 25 nm. In embodiments where selector nodes 38 a-c comprise chalcogenide materials of OTS switches, the fifth thickness h₅ has a thickness selected to be the range between about 5 nm and 50 nm, for example 25 nm, and the sixth thickness h₆ has a thickness selected to be the range between about 10 nm and 100 nm, for example 50 nm.

In connection with the discussion above, a person having ordinary skill in the art will understand that choosing materials coupled to storage nodes and selector nodes to optimize the performance of a memory cell with respect to their electrical resistances and thermal resistances can have tradeoffs. For example, in FIGS. 2A and 2B, choosing a metallic material to serve as top and bottom electrodes 32 a and 36 a of the storage node 34 a can desirably reduce first and third LRS and HRS resistances R_(LRS1), R_(LRS3), R_(HRS1), and R_(HRS3). However, such a choice can undesirably reduce first and second thermal resistances R_(TH1) and R_(TH2) Embodiments that minimize such tradeoffs are now disclosed herein.

FIGS. 3A and 3B illustrate cross-sectional views of a portion of a cross point memory array 80 viewed from a direction parallel to the x-direction and the y-direction, respectively. The cross-point memory array 80 is configured as fully-confined array architecture described above. The cross sectional views are annotated with a circuit representation demonstrating relevant resistive elements during an access operation of a memory cell 50 a as described above. Similar to the cross-point array 10 of FIGS. 2A and 2B, the cross-point array 80 includes memory cells disposed between column lines 20 and row lines 22.

According to the illustrated embodiment in FIGS. 3A and 3B, a memory cell includes a bottom electrode, a chalcogenide material element disposed on the bottom electrode, and a top electrode disposed on the chalcogenide material element. The top electrode includes a top thermally insulating region over the first electrode, where the thermally insulating region comprises carbon and has a first thermal resistivity. Top electrode additionally includes a top metallic contact region interposed between the chalcogenide material element and the thermally insulating region, where the metallic contact material has a second thermal resistivity lower than the first thermal resistivity.

Additionally, the chalcogenide material element has top and bottom surfaces and first and second sidewalls extending between top and bottom surfaces, and the memory cell further includes a plurality of sidewall thermal insulators formed over first and second sidewalls.

In particular, the cross-point memory array 80 of FIGS. 3A and 3B includes memory cells 50 a-50 c. Memory cells 50 a-50 c include bottom electrodes including bottom thermally insulating regions 60 a-60 c and bottom metallic contact regions 58 a-58 c disposed on row lines (not shown). In one embodiment, bottom thermally insulating regions 60 a-60 c are disposed on row lines 22 and may include carbon. Bottom thermally insulating regions 60 a-60 c can include carbon in various forms, including graphitic carbon, diamond-like carbon, and amorphous carbon, among others. Bottom thermally insulating regions 60 a-60 c including carbon can be formed using various processing techniques, including chemical vapor deposition, plasma-enhanced chemical vapor deposition, physical vapor deposition, among others.

In another embodiment, bottom metallic contact regions 58 a-58 c are disposed on thermally insulating regions 60 a-60 c and comprise metallic materials. Bottom metallic contact regions 58 a-58 c include suitable conductive and/or semiconductive materials including n-doped poly silicon and p-doped poly silicon, metals including Al, Cu, Ni, Cr, Co, Ru, Rh, Pd, Ag, Pt, Au, Ir, Ta, and W, conductive metal nitrides including TiN, TaN, WN, and TaCN, conductive metal silicides including tantalum silicides, tungsten silicides, nickel silicides, cobalt silicides, and titanium silicides, and conductive metal oxides including RuO₂.

In some embodiments, bottom thermally insulating regions 60 a-60 c are in direct contact with bottom metallic contact regions 58 a-58 c. In other embodiments, intervening regions may be present that can include materials in bottom thermally insulating regions 60 a-60 c and bottom metallic contact regions 58 a-58 c.

Additionally, memory cells 50 a-50 c include chalcogenide material elements 56 a-56 c disposed on bottom metallic contact regions 58 a-58 c. In one embodiment, chalcogenide material elements 56 a-56 c can be storage nodes described in connection with FIGS. 2A and 2B. In this embodiment, there can be selector nodes coupled elsewhere (not shown in FIGS. 3A and 3B), for example, coupled to bottom thermally insulating regions 60 a-60 c. Selector nodes can be part of various selector devices described above, including, for example, BJTs and OTSs. In another embodiment, chalcogenide material elements 56 a-56 c can be selector nodes described in connection with FIGS. 1, 2A, and 2B. In this embodiment, there can be storage nodes coupled elsewhere (not shown in FIGS. 3A and 3B), for example, coupled to bottom thermally insulating regions 60 a-60 c.

Additionally, memory cells 50 a-50 c include top electrodes including top thermally insulating regions 52 a-52 c and top metallic contact regions 54 a-54 c disposed on chalcogenide material elements 56 a-56 c. In one embodiment, top metallic contact regions 54 a-54 c are disposed on chalcogenide material elements 56 a-56 c and comprise metallic materials. Top metallic contact regions 54 a-54 c include suitable conductive and/or semiconductive materials similar to bottom metallic contact regions 58 a-58 c described above.

In another embodiment, top thermally insulating regions 52 a-52 c are disposed on top metallic contact regions 54 a-54 c and include carbon. Top thermally insulating regions 52 a-52 c can include carbon in similar forms and be formed using similar processing techniques as in bottom thermally insulating regions 60 a-60 c.

In some embodiments, bottom thermally insulating regions 60 a-60 c are in direct contact with bottom metallic contact regions 58 a-58 c. In other embodiments, intervening regions may be present that can include materials in bottom thermally insulating regions 60 a-60 c and bottom metallic contact regions 58 a-58 c.

In addition, in some embodiments, chalcogenide material elements 56 a-56 c can be in direct contact with one or both of top and bottom metallic contact regions 54 a-54 c and 58 a-58 c. In other embodiments, intervening regions may be present that can include materials in chalcogenide material elements 56 a-56 c and top and bottom metallic contact regions 54 a-54 c and 58 a-58 c.

According to the illustrated embodiment of FIG. 3A, chalcogenide material elements 56 a and 56 b have top and bottom surfaces and first and second sidewalls extending between top and bottom surfaces along the z-direction. In the fully-confined array architecture of the cross-point memory array 80, first and second sidewalls are separated in the y-direction by a distance spanning one cell dimension in the y direction (which is similar to the third lateral dimension in the x-direction d_(3a) in FIG. 2A, not illustrated here for clarity). In this configuration, memory cells 50 a and 50 b include first sidewall thermal insulators 72 formed over first and second sidewalls. The first sidewall thermal insulators 72 includes a plurality of sidewall materials, e.g., sidewall layers 72-1 to 72-n (not labeled individually in FIG. 3A for clarity), to provide sufficient thermal insulation to improve programming efficiency of the chalcogenide material element of a target memory cell, and to provide improved immunity against program disturb, as discussed above in connection with FIGS. 2A and 2B. In the example embodiment of FIG. 3A, the chalcogenide material element of the target cell can be 56 a, and the chalcogenide material element of the victim cell can be 56 b adjacent to each other along a common column line 20. Each of the first sidewall thermal insulators 72 includes first through nth sidewall layers. In the illustrated example, by way of an example only, each of the first sidewall thermal insulators 72 includes first through fifth sidewall layers 72-1-72-5 on the first and second sidewalls, where the first sidewall layer 72-1 can be in contact with first and second sidewalls. According to one embodiment, first and second sidewall layers comprise first and second dielectric materials D1 and D2, where each of the first and second sidewall layers have an atomic element not included in the other sidewall layer. According to another embodiment, the sidewall layers can have an alternating arrangement, such that each of first, third, and fifth sidewall layers comprise D1 and each of second and fourth sidewall layers comprise D2 (i.e., D1/D2/D1/D2/D1). Other embodiments are possible, where each third through fifth sidewall layers 72 c-72 e can comprise third through fifth dielectric materials D3-D5 that can be one of D1 or D2 or other materials.

In one embodiment, each of the first through nth sidewall layers 72-1 to 72-n of first sidewall thermal insulators 72 can have a thickness ranging from about 1 to 10 nm, for instance about 2 nm. In another embodiment, each of the first through nth sidewall layers 72-1 to 72-n of the first sidewall thermal insulators 72 can have a thickness ranging from about 2 to 5 nm, for instance about 3.5 nm. In addition, in some embodiments, the thicknesses of sidewall layers 72-1 to 72-n are substantially the same. In other embodiments, the thicknesses of sidewall layers 72-1 to 72-n are substantially different from one another.

In one embodiment, first sidewall thermal insulators 72 can have 1 to 20 sidewall layers (i.e., n can be 1 to 20), for instance 10 sidewall layers. In another embodiment, first sidewall thermal insulators 72 can have 2 to 10 sidewall layers (i.e., n can be 2 to 10), for instance 6 sidewall layers. In yet another embodiment, first sidewall thermal insulators 72 can have 3 to 7 sidewall layers (i.e., n can be 3 to 7), for instance 5 sidewall layers.

In one embodiment, each of the first through nth sidewall layers of the first sidewall thermal insulators 72 can include oxides such as SiO₂, ZrO₂, Hf0₂, Al₂O₃, NiO, TiO₂, Ta₂O₅, ThO₂, HfSiO₄, ZrSiO₄, Mg₂SiO₄, MgO, BeO, and oxides of lanthanide series, among other oxides. In another embodiment, each of the first through nth sidewall layers of the first sidewall thermal insulators 72 can include nitrides or carbides such as Si3N₄ and SiC, among other nitrides and carbides.

Each of the first through nth sidewall layers of first sidewall thermal insulators 72 can be formed using a suitable deposition technique. For example, the first through nth sidewall layers can be formed using various processing techniques, including atomic layer deposition, chemical vapor deposition, plasma-enhanced chemical vapor deposition, physical vapor deposition, among others. A person skilled in the art will understand that the choice of a processing technique depends on many factors, e.g., as the availability of the precursor material, feature size and/or aspect ratio of an opening through which the material to be deposited is to travel, cost, and conformality of the deposited material, among others.

FIG. 3B similarly illustrates chalcogenide material elements 56 a and 56 c having top and bottom surfaces and third and fourth sidewalls extending between top and bottom surfaces along the z-direction. In the fully-confined array architecture of the cross-point memory array 80, third and fourth sidewalls are separated in the x-direction by a distance spanning one cell dimension in the x direction (which is similar to the third lateral dimension in the x-direction dab in FIG. 2B, not illustrated here for clarity). In addition, third and fourth sidewalls are substantially perpendicular to first and second sidewalls. In this configuration, memory cells 50 a and 50 c include second sidewall thermal insulators 74 formed over third and fourth sidewalls. Similar to first sidewall thermal insulators 72, second sidewall thermal insulators 74 include a suitable number of sidewall materials, e.g., layers, to provide sufficient thermal insulation to improve programming efficiency of the chalcogenide material element of a target memory cell, and to provide improved immunity against program disturb, as discussed above in connection with FIGS. 2A and 2B. In the example embodiment of FIG. 3B, the chalcogenide material element of the target cell can be 56 a, and the chalcogenide material element of the adjacent victim cell can be 56 c along a common row line 22. Each of the second sidewall thermal insulators 74 includes (n+1)th through mth sidewall layers (not labeled individually in FIG. 3B for clarity). In the illustrated example, by way of an example only, each of the second sidewall thermal insulators 74 includes sixth through tenth sidewall layers 74-6 to 74-10 on third and fourth sidewalls, where the sixth sidewall layer 74-6 can be in contact with third and fourth sidewalls. The materials, thicknesses, and the number of (n+1)th through mth sidewall layers of the second sidewall thermal insulators 74 can be similar to those described for first sidewall thermal insulators 72. In addition, the sidewall layers of the second sidewall thermal insulators 74 can be formed using similar techniques as those described for first sidewall thermal insulators 72.

A person skilled in the art will understand that a choice of certain material combinations for different regions of the memory cell and the array can be made to optimize certain aspects of the performance of the memory cell. These aspects are discussed by referring to a circuit path 14. In the fully-confined array architecture of the cross-point memory array 80 in FIGS. 3A and 3B, the memory cell 50 a may be accessed in a bit-addressable mode by application of an access voltage V_(ACCESS) across the a first terminal 14 a and a second terminal 14 b of the access circuit path 14. The first and second terminals can represent an nth column 20 and a mth row 22. V_(ACCESS) and the associated current I_(ACCESS) will result in energy dissipation at various points along the access circuit path 14.

The access circuit path 14 includes first through third resistors 62, 64, and 66 connected in electrical series between first and second terminals 14 a and 14 b. Similar to the access circuit path 12 in FIGS. 2A and 2B, the first through third resistors 62, 64, and 66 can have first through third LRS resistances R′_(LRS1), R′_(LRS2), and R′_(LRS3) and HRS resistances R′_(HRS1), R′_(HRS2), and R′_(HRS3). Contributions to LRS and HRS resistances can originate from various regions across the memory cell 50 a, which is a target memory cell in this example. For example, regions that contribute to R′_(LRS1) and R′_(HRS1) can include a bulk material of the top thermally insulating region 52 a, a bulk material of the top metallic contact region 54 a, and a first interface between the top metallic contact region 54 a and the storage node 56 a. Additionally, regions that contribute to R′_(LRS2) and R′_(HRS2) can include a bulk material of the storage node 56 a. Additionally, regions that contribute to R′_(LRS3) and R′_(HRS3) can include a second interface between the storage node 56 a and the bottom metallic contact region 58 a, a bulk material of the bottom metallic contact region 58 a, and a bulk material of the bottom thermally insulating region 60 a. It is to be understood that while other regions may also contribute substantially to the overall resistance between the first and second terminals 14 a and 14 b, only first through third resistors 62, 64, and 66 are represented in the access circuit path 14 for clarity. In addition, other circuit paths can exist, for example, through the second memory cell 50 b, which are not shown nor discussed for clarity.

In the illustrated embodiment of FIGS. 3A and 3B, by choosing a suitable material for the top metallic contact region 54 a as discussed above, the contribution of the first interface between the top electrode and the storage node 56 a to R′_(LRS1) and R′_(HRS1) can be substantially reduced compared to embodiments that do not include the top metallic contact region 54 a. Similarly, by choosing a suitable material for the bottom metallic contact region 58 a as discussed above, the contribution of the second interface between the bottom electrode and the storage node 56 a to R′_(LRS3) and R′_(HRS3) can be substantially reduced compared to embodiments that do not include the bottom metallic contact region 58 a. This is because interfaces formed by top and bottom thermally insulating regions 52 a and 60 a in contact with the chalcogenide material element 56 a can have substantially higher contact resistances compared interfaces formed by top and bottom metallic contact regions 54 a and 58 a in contact with the chalcogenide material element 56 a.

In one embodiment, the contribution of interfacial resistances of first and second interfaces to first and third LRS resistances R′_(LRS1) and R′_(LRS3) and first and third FIRS resistances R′_(HRS1) and R′_(HRS3) is below about 1×10⁻⁶ Ohm cm². In another embodiment, the contribution of interfacial resistances of first and second interfaces to first and third LRS resistances R′_(LRS1) and R′_(LRS3) and first and third FIRS resistances R′_(HRS1) and R′_(HRS3) is below about 1×10⁻⁷ Ohm cm². In yet another embodiment, the contribution of interfacial resistances of first and second interfaces to first and third LRS resistances R′_(LRS1) and R′_(LRS3) and first and third HRS resistances R′_(HRS1) and R′_(HRS3) is below about 5×10⁻⁸ Ohm cm².

By reducing contributions of first and second interfaces to LRS and FIRS resistances as described above in the embodiment of FIGS. 3A and 3B, a higher ON/OFF ratio can be achieved. This is because as discussed above, the ON/OFF ratio can be proportional to the ratio (R′_(HRS1)+R′_(HRS2)+R′_(HRS3))/(R′_(LRS1)+R′_(LRS2)±R′_(LRS3)), and when R′_(HRS2)>>R′_(HRS1)+R′_(HRS3) and R′_(LRS2)>>R′_(LRS1)+R′_(LRS3), the ON/OFF ratio can be dominated by the ratio R′_(HRS2)/R′_(LRS2). Under this circumstance, the ON/OFF ratio can be desirably dominated by the resistance values of the bulk resistance of the storage node 56 a in SET and RESET states. Thus, from an ON/OFF ratio point of view, an implementation exemplified in FIGS. 3A and 3B can desirably have relatively low LRS and HRS resistances R′_(LRS1), R′_(LRS3), R′_(HRS1), and R′_(HRS3) of the first and third resistors 62 and 66 and relatively high LRS and HRS resistances R′_(LRS2) and R′_(HRS2) of the second resistor 64.

Additionally, in the illustrated embodiment of FIGS. 3A and 3B, by choosing a suitable material for the top metallic contact region 54 a as discussed above, higher energy efficiencies of SET and RESET operations can also be achieved. This is because it may be desirable to have self-heating of the storage node dominate over heats generated in other regions. From this standpoint, it may be desirable to have R′_(HRS2)>>R′_(HRS1)+R′_(HRS3) and R′_(LRS2)>>R′_(LRS1)+R′_(LRS3). When a voltage V_(ACCESS) is applied between the first and second terminals 14 a and 14 b of the access circuit path 14, voltages proportional to respective LRS and HRS resistances can drop across first, second, and third resistors 62, 64, and 66. In particular, when V_(ACCESS)=V_(RESET) is applied between the first and second terminals 14 a and 14 b, first, second, and third voltages V′_(RESET1), V′_(RESET2), and V′_(RESET3) can drop across first, second, and third resistors 62, 64, and 66, respectively. In addition, the resulting current I_(RESET)=V_(RESET)/(R′_(LRS1)+R′_(LRS2)+R′_(LRS3)) can result in generation of first, second, and third RESET heats Q′_(REST1)=I_(RESET) ²R′_(LRS1) and Q′_(RST2)=I_(REST) ²R′_(LRS2), and Q′_(RST3)−I_(RESET) ²R′_(LRS3), respectively. Thus, by having R′_(LRS2)>>R′_(LRS1)+R′_(LRS3), more of the access energy is spent on self-heating the chalcogenide material element 56 a compared to the interfaces.

Similarly, when V_(ACCESS)=V_(SET) is applied between the first and second terminals 14 a and 14 b, first, second, and third voltages V′_(SET1), V′_(SET2), and V′_(SET3) can drop across first, second, and third resistors 62, 64, and 66, respectively. In addition, the resulting current I_(SET)=V_(SET)/(R′_(HRS1)+R′_(HRS2)+R′_(HRS3)) can result in the generation of first, second, and third SET heats Q′_(SET1)=I_(SET)=I_(SET) ²R′_(HRS1) and Q′_(SET2)−I_(SET) ²R′_(HRS2), and Q′_(SET3)−I_(SET) ²R′_(HRS3), respectively. Thus, by having R′_(HRS2)>>R′_(HRS1)+R′_(HRS3), more of the access energy is spent on heating the chalcogenide material element 56 a versus the interfaces.

Furthermore, in the illustrated embodiment of FIGS. 3A and 3B, by choosing a suitable material for top and bottom insulating regions 52 a and 60 a and for first and second sidewall thermal insulators 72 and 74 as discussed above still higher energy efficiency of SET and RESET operations can be achieved by more efficiently confining the heat generated in the storage node in response to dissipation of power during SET and RESET operations. As illustrated in FIGS. 3A and 3B, there can be heat loss in six directions. A first heat Q′₁ can be lost from the storage node 56 a in the z-direction towards the column line 20. A second heat Q′₂ can be lost from the storage node 56 a in the z-direction towards the row line 22. A third heat Q′₃ can be lost from the storage node 56 a in opposite y-directions towards adjacent storage nodes 56 b and 56 h (not shown). A fourth heat Q′₄ can be lost from the storage node 56 a in opposite x-directions towards adjacent storage nodes 54 c and 54 e (not shown).

First through fourth heats Q′₁-Q′₄ can be characterized as being inversely proportional to first through fourth thermal resistances array architecture of the cross-point memory array 80, contributions to first through fourth thermal resistances R′T_(H1)-R′_(TH4) can originate from various regions connected to the memory cell 50 a, which can be a target memory cell. For example, regions that contribute to R′_(TH1) and R′_(TH2) can include bulk materials of the top and bottom thermally insulating regions 52 a and 60 a. Thus, by choosing a suitable material for top and bottom insulating regions 52 a and 60 a, e.g., a carbon-based material, Q′₁ and Q′₂ can be substantially reduced compared to embodiments that do not include top and bottom insulating regions 52 a and 60 a.

In this connection, choosing materials having suitable thermal resistivities can be important for minimizing Q′₁ and Q′₂. In one embodiment, a first ratio of the thermal resistivity corresponding to top thermally insulating regions 52 a-52 c and the thermal resistivity corresponding to top metallic contact regions 54 a-54 c has a range between about 1 and 500. In another embodiment, the first ratio has a range between about 1 and 200. In yet another embodiment, the first ratio has a range between about 10 and 50. Similarly, a second ratio of the thermal resistivity corresponding to bottom thermally insulating regions 60 a-60 c and the thermal resistivity corresponding to bottom metallic contact regions 58 a-58 c can have similar ranges and values as the first ratio.

Additionally, regions that contribute to R′TH3 can include interfaces and bulk materials formed between the storage node 56 a and sidewall layers 72-1 to 72-n of first sidewall thermal insulators 72. Similarly, regions that contribute to R′_(TH4) can include interfaces and bulk materials formed between the storage node 56 a and sidewall layers 74¬(n+1) to 72 m of second sidewall thermal insulators 74. Thus, by choosing suitable materials and numbers of sidewall layers for first and second sidewall thermal insulators 72 and 74 as discussed above, Q′₃ and Q′₄ can be substantially reduced compared to embodiments that do not include first and second sidewall thermal insulators 72 and 74.

A person skilled in the art will understand that having first and second sidewall thermal insulators 72 and 74 including a plurality sidewall layers can increase R′_(TH3) and R′_(TH4) by more than a mere linear sum proportional to thicknesses and thermal resistance values of the individual layers. This is because the presence of interfaces can increase the thermal resistance independently of the bulk material. For example, having first and second sidewall layers of first and second dielectric materials having a combined first thickness can have lower thermal resistance compared to first through tenth sidewall layers of alternating first and second dielectric materials having a combined second thickness equal to the first thickness.

Similarly, higher R′_(TH3) and R′_(TH4) resulting from having first and second sidewall thermal insulators 72 and 74 can reduce program disturb of adjacent cells. As discussed above in connection with FIGS. 2A and 2B, program disturb of adjacent cells depend on the increased temperature of the adjacent victim cell induced by programming a target cell. In this connection, minimizing loss of third and fourth heats Q′3 and Q′4 in FIGS. 3A and 3B, which can be achieved by maximizing R′_(TH3) and R′_(TH4) discussed above, can lead to an improvement in program disturb performance of the cross-point memory array 80.

According to the embodiments of FIGS. 3A and 3B, column lines 20 have a first thickness h1 and the storage node 56 a-c have a third thickness h₃ similar to the first and third thicknesses of FIGS. 2A and 2B. In addition, top thermally insulating regions 52 a-c and top metallic contact regions 54 a-c have thicknesses h_(2A) and h_(2B), respectively. In addition, bottom metallic contact regions 58 a-c and bottom thermally insulating regions 60 a-c have thicknesses h_(4A) and h_(4B), respectively. In one embodiment, each of the thicknesses h_(2A) and h_(4B) of top and bottom thermally insulating regions 52 a-c and 60 a-c can be selected to be in the range between 10 and 50 nm. In another embodiment, each of the thicknesses h_(2A) and h_(4B) of top and bottom thermally insulating regions 52 a-c and 60 a-c can be selected to be in the range between 20 and 30 nm. In one embodiment, each of the thicknesses h_(2B) and h_(4A) of top and bottom metallic contact regions 54 a-c and 58 a-c can be selected to be in the range between 5 and 30 nm. In another embodiment, each of the thicknesses h_(2B) and h_(4A) of top and bottom metallic contact regions 54 a-c and 58 a-c can be selected to be in the range between 10 and 20 nm. Other dimensions not illustrated, for example the fifth thickness h₅ and the sixth thickness h₆ can be similar to the dimensions discussed above in connection with FIGS. 2A and 2B.

FIGS. 4A and 4B illustrate cross-sectional views of a portion of a cross point memory array 110 viewed from a direction parallel to the x-direction and the y-direction, respectively, according to another embodiment. Similar to the cross-point array 80 of FIGS. 3A and 3B, the cross-point array 110 includes memory cells disposed between column lines 20 and row lines 22. In contrast to the fully-confined array architecture described above in connection with FIGS. 3A and 3B, the array architecture in FIGS. 4A and 4B has a top thermally insulating region, a top metallic contact region, and a chalcogenide material element forming a continuous line along with the column line 20. In addition, the array architecture in FIGS. 4A and 4B has bottom electrodes forming a thin wall structure extending in the row direction. The array architecture is referred to herein as a wall array architecture.

According to the illustrated embodiment in FIGS. 4A and 4B, a memory cell includes a bottom electrode, a chalcogenide material element disposed on the bottom electrode, and a top electrode disposed on the chalcogenide material element. The top electrode includes a top thermally insulating region over the first electrode, where the thermally insulating region comprises carbon and has a first thermal resistivity. Top electrode additionally includes a top metallic contact region interposed between the chalcogenide material element and the thermally insulating region, where the metallic contact layer has a second thermal resistivity lower than the first thermal resistivity.

Additionally, the chalcogenide material element has top and bottom surfaces and first and second sidewalls extending between top and bottom surfaces, and the memory cell further includes a plurality of sidewall thermal insulators formed over first and second sidewalls.

The cross-point memory array 110 of FIGS. 4A and 4B includes memory cells 90 a-90 c. Memory cells 90 a-90 c include bottom electrodes 98 a and 98 b disposed on row lines (not shown). Bottom electrodes 98 a and 98 c in FIG. 4B form a thin wall extending in the x-direction having a wall length similar to the fourth lateral dimension in the x-direction d4 b corresponding to the bottom electrodes 36 a and 36 c in FIG. 2B. However, unlike FIG. 2B, the bottom electrodes 98 a and 98 b in FIG. 4A have a wall thickness substantially thinner than the fourth lateral dimension in the y-direction d4 a corresponding to the bottom electrodes 36 a and 36 b in FIG. 2A. The wall thickness can be any suitable thickness substantially less than the fourth lateral dimension d4 a and chosen to dissipate sufficient energy to as a heater for changing the phase of the chalcogenide material element during either one or both of SET and RESET operations. For example, in one embodiment, the wall thickness is between about 10% and about 50% of the fourth lateral dimension d4 a. In another embodiment, the wall thickness is between about 20% and about 40% of the fourth lateral dimension d4 a, for instance about 25%. Due to the thin wall configuration, the bottom electrodes 98 a-98 c dissipates a substantial amount of energy in both SET and RESET operations and can function as a heater for the chalcogenide material element.

Additionally, in contrast to the fully-confined array architecture described above in connection with FIGS. 3A and 3B, the wall array architecture in FIGS. 4A and 4B has chalcogenide material elements 96 a and 96 c disposed on bottom electrodes 98 a and 98 c, top metallic contact regions 94 a and 94 c disposed on chalcogenide material elements 96 a and 96 c, and top thermally insulating regions 92 a and 92 c disposed on metallic contact regions 94 a and 94 c. In this embodiment, chalcogenide material elements 96 a and 96 c, top metallic contact regions 94 a and 94 c, and top thermally insulating regions 92 a and 92 c form continuous lines along with the column line 20. In one embodiment, chalcogenide material elements 96 a-96 c can be storage nodes In this embodiment, there can be selector nodes coupled elsewhere (not shown in FIGS. 4A and 4B), for example, coupled to bottom electrodes 98 a-98 c. The selector nodes can be part of various selector devices described above, including, for example, BJTs and OTSs.

Top metallic contact regions 94 a-94 c include suitable conductive and semiconductive materials similar to top metallic contact regions of FIGS. 3A and 3B. In addition, top thermally insulating regions 92 a-92 c can include carbon in similar forms as in top thermally insulating regions of FIGS. 3A and 3B, and can be formed using similar processing techniques.

According to the illustrated embodiment of FIG. 4B, chalcogenide material elements 96 a and 96 c have top and bottom surfaces and first and second sidewalls extending between top and bottom surfaces along the z-direction. In the wall array architecture of the cross-point memory array 110, first and second sidewalls extend in the y-direction to span one column line dimension in the y direction (which is similar to the first lateral dimension in the y-direction d_(1a) in FIG. 2A, not illustrated here for clarity). In this configuration, memory cells 90 a and 90 b include a plurality of first sidewall thermal insulators 104 formed over first and second sidewalls. Similar to FIG. 3B, the plurality of first sidewall thermal insulators 104 includes a suitable number of layers to provide sufficient thermal insulation to improve programming efficiency of the chalcogenide material element of a target memory cell, and to provide improved immunity against program disturb, as discussed above in connection with FIGS. 2A and 2B. In the example embodiment of FIG. 4B, the chalcogenide material element of the target cell can be 96 a, and the chalcogenide material element of the victim cell can be 96 b along a common row line 22 (not shown). Each of the first sidewall thermal insulators 104 can include first through nth sidewall layers, similar to as discussed in FIGS. 3A and 3B. In addition, the materials, thicknesses, and the number of first through nth sidewall layers of the first sidewall thermal insulators 104 can be similar to those described for the first sidewall thermal insulators in FIGS. 3A and 3B. In addition, the sidewall layers of the second sidewall thermal insulators 104 can be formed using similar techniques as those described for the first sidewall thermal insulators in FIGS. 3A and 3B.

Although this invention has been described in terms of certain embodiments, other embodiments that are apparent to those of ordinary skill in the art, including embodiments that do not provide all of the features and advantages set forth herein, are also within the scope of this invention. Moreover, the various embodiments described above can be combined to provide further embodiments. In addition, certain features shown in the context of one embodiment can be incorporated into other embodiments as well. Accordingly, the scope of the present invention is defined only by reference to the appended claims. 

1. (canceled)
 2. A memory element, comprising: a first electrode; a chalcogenide material element located on the first electrode, wherein the chalcogenide material element is a selector node; a second electrode disposed on the chalcogenide material element and comprising a thermally insulating carbon region and a metallic contact region located between the chalcogenide material element and the thermally insulating carbon region; and a metallic access line coupled with the thermally insulating carbon region.
 3. The memory element of claim 2, wherein the thermally insulating carbon region is associated with a thermal resistivity different from the metallic contact region.
 4. The memory element of claim 2, wherein: the thermally insulating carbon region is associated with a first thermal resistivity; and the metallic contact region is associated with a second thermal resistivity lower than the first thermal resistivity.
 5. The memory element of claim 2, further comprising: a storage node that is electrically coupled to the selector node via the first electrode.
 6. The memory element of claim 2, wherein a resistance of a portion of the chalcogenide material element is greater than a combined resistance of a portion of the thermally insulating carbon region, a portion of the metallic contact region, and an interface between the metallic contact region and the chalcogenide material element.
 7. The memory element of claim 2, wherein the metallic access line is coupled with the memory element and a second memory element.
 8. The memory element of claim 7, further comprising: a sidewall insulator located between the memory element and the second memory element, wherein the sidewall insulator comprises at least two layers.
 9. The memory element of claim 8, wherein the at least two layers comprise: a first layer adjacent to the memory element; and a second layer located between the first layer and the second memory element.
 10. The memory element of claim 9, wherein the first layer comprises a material composition different from the second layer.
 11. A device comprising: a first electrode; a chalcogenide material element located on the first electrode, wherein the chalcogenide material element is a selector node of a memory cell; a second electrode disposed on the chalcogenide material element, wherein the second electrode comprises a thermally insulating carbon region and a metallic contact region between the chalcogenide material element and the thermally insulating carbon region; and a sidewall insulator in contact with each of the first electrode, the chalcogenide material element, and the second electrode.
 12. The device of claim 11, wherein the thermally insulating carbon region has a first thermal resistivity higher than a second thermal resistivity of the metallic contact region.
 13. The device of claim 11, wherein the first electrode electrically is configured to couple a storage node to the selector node.
 14. The device of claim 11, wherein the sidewall insulator comprises a plurality of insulating layers.
 15. The device of claim 11, wherein the sidewall insulator is adjacent to the selector node.
 16. A device comprising: a first electrode; a chalcogenide material element located on the first electrode; a second electrode located on the chalcogenide material element; and an access line extending in a first direction, wherein the access line and the second electrode have a same nominal width in a second direction different from the first direction.
 17. The device of claim 16, wherein the second electrode comprises a thermally insulating region and a metallic contact region located between the chalcogenide material element and the thermally insulating region.
 18. The device of claim 17, wherein: the thermally insulating region comprises carbon and is associated with a first thermal resistivity; and the metallic contact region is associated with a second thermal resistivity lower than the first thermal resistivity.
 19. The device of claim 17, further comprising: a sidewall insulator adjacent to each of the first electrode, the chalcogenide material element, and the second electrode.
 20. The device of claim 16, wherein the access line is in contact with the second electrode and extends in the first direction.
 21. The device of claim 16, wherein the second direction is perpendicular to the first direction. 